KR20060119636A - Zooming method of digital image processing apparatus wherein focusing is performed - Google Patents

Abstract

A zooming method of a digital image processing apparatus performing focusing is provided to allow a user to watch a distinct image even while the user is pushing a zooming button. A digital image processing apparatus includes a zooming button, a zoom lens and a focus lens and moves the zoom lens to a set moving distance for a period of time during which the zooming button is pushed. A target position of the zoom lens, which corresponds to the set moving distance from the current position of the zoom lens, is obtained. A target position of the focus lens, which corresponds to the target position of the zoom lens, is acquired. The zoom lens and the focus lens are simultaneously moved to their target positions. The focusing operation of the focus lens is performed, corresponding to the zooming operation of the zoom lens.

Description

Zooming method of digital image processing apparatus wherein focusing is performed}

1 is a rear view showing a rear appearance of a digital camera as a digital image processing apparatus according to the present invention.

FIG. 2 is a cross-sectional view illustrating an internal configuration and an optical path of the optical system-tube module of the digital camera of FIG. 1.

FIG. 3 is a diagram illustrating a state in which the zoom lens and the focus lens of FIG. 2 are driven to explain the zooming algorithm performed in the photographing operation of the digital camera of FIG. 1.

FIG. 4 is a graph illustrating a focusing range of the focus lens of FIG. 3 corresponding to each position of the zoom lens of FIG. 3 in order to explain the zooming algorithm of the digital camera of FIG. 1.

5 is a flowchart illustrating a zooming algorithm performed by the digital camera of FIG. 1.

<Explanation of symbols for the main parts of the drawings>

1 ... digital camera, 13 ... shutter release button,

15 ... function buttons, 15 _R ... self-timer / right button,

15 _L ... flash / left button, 15 _D ... macro / down button,

15 _U ... Voice-Memo / Up Button, 15 _M ... Menu / Select-OK Button,

35 ... color LCD panel, 39 _W ... wide-zoom button,

39 _T ... telephoto-zoom button, ZL ... zoom lens,

FL ... focus lens, 701 ... 1st guide bar,

702 ... 2nd guide bar, F _SL ... focusing upper limit position,

Z _HL ... zoom upper limit position, F _A , F _B , F _C ... positions of focus lens,

F _LA , F _LB , F _LC ... lower positions of each focusing range,

F _HA , F _HB , F _HC ... upper positions of each focusing range.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a zooming method of a digital image processing apparatus. More particularly, the present invention relates to a digital image processing apparatus including a zooming button, a zoom lens, and a focus lens and moving a zoom lens during a time when a zooming button is pressed. It relates to the zooming method.

Conventional digital image processing apparatus, for example, a digital camera of 2004 US Patent No. 119,876 (Method of Notification of inadequate picture quality), filed by the applicant, includes a zooming button, a zoom lens, and A focus lens is provided and the zoom lens is moved during the time that the zooming button is pressed.

In the conventional digital image processing apparatus as described above, there is a fundamental problem that the input image displayed during the time when the zoom lens is moved is blurred. Accordingly, the user feels frustrated not to see the clear image during the time to press the zooming button.

SUMMARY OF THE INVENTION An object of the present invention is to provide a zooming method for allowing a user to view a clear image even during a time when a user presses a zooming button in a zooming method of a digital image processing apparatus.

According to an aspect of the present invention, there is provided a zooming button, a zoom lens, and a focusing lens, and a zooming method of a digital image processing apparatus for moving the zoom lens by a set moving distance during a time when the zooming button is pressed. Steps (a) to (c). In the step (a), the target position of the zoom lens corresponding to the set moving distance from the current position of the zoom lens is obtained. In the step (b), the target position of the focus lens corresponding to the target position of the zoom lens is obtained. In the step (c), the zoom lens and the focus lens are simultaneously moved to the respective target positions.

According to the zooming method of the digital image processing apparatus of the present invention, the focusing operation of the focus lens is performed corresponding to the zooming operation of the zoom lens. Accordingly, since the input image displayed during the time when the zoom lens is moved is not blurred, the user can see the clear image even during the time when the zooming button is pressed.

Hereinafter, preferred embodiments according to the present invention will be described in detail.

Referring to FIG. 1, the digital camera 1 as a digital image processing apparatus according to the present invention includes a shutter release button 13, function buttons 15, a color LCD panel 35, and a wide angle zoom. zoom button 39 _W , telephoto-zoom button 39 _T , and the like.

When the user presses the shutter release button 13, a shooting operation is performed, and auto focusing is performed as one step of this shooting operation.

The function buttons 15 are used by the user to perform specific functions of the digital camera 1 while being used as direction-shift buttons and the like of the activation cursor in the menu screen of the color LCD panel 35. The function buttons 15 are self-timer / right button 15 _R , flash / left button 15 _L , macro / down button 15 _D , voice-memo / up button 15 _U , and menu / select - includes a confirmation button (15 _M).

The user and the wide angle (wide angle) - the zoom button (39w) or telephoto (telephoto) - pressing the zoom button (39 _T), is a zoom motor driving the zoom lens is moved. In this regard, FIG. 2 shows the internal configuration and the optical path of the optical-tube module of the digital camera 1 of FIG. 1.

Referring to FIG. 2, the optical system-tube module is curved, and has a first lens assembly 10 having positive refractive power, a second lens assembly 20 performing a zooming operation with negative refractive power, and a third having positive refractive power. The lens assembly 30 includes a fourth lens assembly 40 that performs a focusing operation with positive refractive power, and a photoelectric conversion unit 90.

The first lens assembly 10 includes a first lens barrel 14, a G1 lens 11, a G3 lens 13, and a prism 12. The first lens barrel 14 includes a front opening facing the subject and a side opening perpendicular to the opening. The G1 lens 11 is provided in the front opening of the first lens barrel 14. The G3 lens 13 is provided in the side opening of the first lens barrel 14. The prism 12 switches the traveling direction of the light at a right angle so that the light incident on the G1 lens 11 is directed to the G3 lens 13.

The fourth lens assembly 40 as a focus lens includes a lens barrel 41 and a plurality of lenses 46 and 45. Similarly, the second lens assembly 20 as a zoom lens includes a lens barrel and a plurality of lenses. The third lens assembly 30 which performs the function of the auxiliary lens includes a lens barrel and a fixed lens.

The photoelectric conversion unit 90 includes an optical low pass filter 91 and a charge coupled device 95. The CCD 95 converts light passing through the lenses into an electrical signal and may be replaced with a complementary metal oxide semiconductor (CMOS).

In the digital camera 1, the image magnification according to the position of the second lens assembly 20 as the zoom lens is set in advance, and the focal length according to the position of the fourth lens assembly 40 as the focus lens is preset. . Thus, the main controller of the digital camera 1 can obtain the focus distance with respect to the position of the fourth lens assembly 40 as the focus lens from the design data of the optical system-tube. Here, the focal length relative to the position of the fourth lens assembly 40 as the focus lens is set differently according to the position of the second lens assembly 20 as the zoom lens (see FIG. 4).

1 and 2, the second lens assembly 20 as the zoom lens moves toward the first lens assembly 10 in units of set movement distances during the time when the wide angle zoom button 39w is pressed. do. In this case, as the focal length becomes shorter and the angle of view widens, the image magnification decreases. In addition, the focusing range of the fourth lens assembly 40 as the focus lens is narrowed (see FIG. 4). Here, corresponding to the position of the second lens assembly 20 as the zoom lens, the fourth lens assembly 40 as the focus lens moves toward the photoelectric conversion unit 90. Related matters will be described in detail with reference to FIGS. 3 to 5.

In contrast, during the time when the telephoto-zoom button 39 _T is pressed, the second lens assembly 20 as the zoom lens moves toward the third lens assembly 30 in units of set movement distances. In this case, as the focal length becomes longer and the angle of view becomes narrower, the image magnification becomes higher. In addition, the focusing range of the fourth lens assembly 40 as the focus lens is widened (see FIG. 4). Here, corresponding to the position of the second lens assembly 20 as the zoom lens, the fourth lens assembly 40 as the focus lens moves the third lens assembly 30. Related matters will be described in detail with reference to FIGS. 3 to 5.

On the other hand, in the focusing mode, the fourth lens assembly 40 as the focus lens is moved within the movement range set corresponding to the current position of the second lens assembly 20 as the zoom lens, and in this process, the high frequency content of the input image signal The position of the fourth lens assembly 40 as this most increasing focus lens is applied as the focus position.

3 illustrates a state in which the zoom lens ZL and 20 and the focus lens FL and 40 of FIG. 2 are driven to explain the zooming algorithm performed in the digital camera 1 of FIG. 1. 4 illustrates a focusing range of the focus lens FL of FIG. 3 corresponding to each position of the zoom lens ZL of FIG. 3 in order to explain the zooming algorithm performed in the digital camera 1 of FIG. 1. 3 and 4, reference numeral 701 designates a first guide bar for moving the zoom lens ZL. Reference numeral 702 denotes a second guide bar located on an extension line of the first guide bar 701 to move the focus lens FL. Reference numeral Z _LL indicates the zoom lens position at the lowest magnification in the movement range of the first guide bar 701. Reference numeral Z _HL is a zooming upper limit position, which indicates the zoom lens position at the highest magnification in the movement range of the first guide bar 701. Reference numeral F _LL indicates the focus lens position of the longest focal length in the movement range of the second guide bar 702. Reference symbol F _SL is a focusing upper limit position when the zoom lens ZL position is the zooming upper limit position Z _HL , and indicates the focus lens position of the shortest focal length in the movement range of the second guide bar 702. . Reference numeral Z indicates the axis of movement of the zoom lens ZL. Reference numeral F denotes an axis of focus lens FL movement. 5 shows a zooming algorithm performed in the digital camera 1 of FIG. The zooming algorithm of FIG. 5 will be described with reference to FIGS. 3 to 5 as follows.

When the current position of the zoom lens ZL is Z _A at the time when the user presses the telephoto-zoom button 39 _T , the main controller of the digital camera 1, for example, the digital camera processor, may be a zoom lens. The target position Z _B of the zoom lens ZL corresponding to the set movement distance from the current position Z _A of ZL is obtained (step S1).

Next, the main controller finds the target position F _B of the focus lens FL corresponding to the target position Z _B of the zoom lens ZL (step S2). Here, the first focusing range F _LA to F _HA of the focus lens FL corresponding to the current position Z _A of the zoom lens ZL, and the focus lens FL corresponding to the target position Z _B of the zoom lens ZL. Using the second focusing range F _LB to F _HB ), the target position F _B of the focus lens FL is obtained. That is, the target position F _B of the focus lens FL is obtained by the ratio of the second focusing range F _LB to F _HB to the first focusing range F _LA to F _HA .

More specifically, the current position of the focus lens FL is F _A , the lower limit position of the first focusing range F _LA to F _HA is F _LA , and the upper limit position of the first focusing range F _LA to F _HA is F. _HA , a target position of the focus lens FL is F _B , a lower limit position of the second focusing range F _LB to F _HB is F _LB , and an upper limit position of the second focusing range F _LB to F _HB is F _HB . The target position F _B of the focus lens FL is obtained by Equation 1 below.

Next, the main controller finds the target moving speed of the focus lens FL corresponding to the set moving speed of the zoom lens ZL (step S3). Here, the focus lens FL so that the time when the zoom lens ZL moves to the target position Z _B of the zoom lens ZL and the time when the focus lens FL moves to the target position of the focus lens FL are the same. The moving speed of is obtained.

Of course, in order to reduce the calculation time of the main controller, the above step S3 may be omitted by setting the appropriate moving speed of the focus lens FL to the moving speed of the zoom lens ZL in advance. For example, the ratio of the moving speed of the focus lens FL to the moving speed of the zoom lens ZL is 0.55 to 0.65.

Next, the main controller simultaneously moves the zoom lens ZL and the focus lens FL to their respective target positions according to the set moving speeds (step S4).

Accordingly, even while the zoom lens ZL moves from the current position Z _A to the target position Z _B , the focusing is performed, so that the user can see a clear image.

Steps S1 to S4 are repeatedly performed while the input of the zooming signal by the user pressing the telephoto-zoom button 39 _T is continued (step S5). When the steps S1 to S4 are performed for the second time, the target position of the focus lens FL is reset to the current position F _B. More specifically, the current position of the focus lens FL is F _B , the lower limit position of the first focusing range is F _LB , the upper limit position of the first focusing range is F _HB , and the target position of the focus lens FL. Is F _C , the lower limit position of the second focusing range is F _LC , and the upper limit position of the second focusing range is reset to F _HC . Therefore, the target position of the focus lens FL is F _C obtained by the following equation (2).

Accordingly, since the focusing is performed even while the user presses the telephoto-zoom button 39 _T , the user can see a clear image.

On the contrary, when the zoom lens ZL is moved from the position of Z _{C to} the position of Z _B while the user presses the wide angle-zoom button 39w, the focus lens FL is expressed by Equation 3 below. ), The target position F _B is obtained.

Therefore, when the zoom lens ZL moves from the position of Z _{B to} the position of Z _A while the user presses the wide angle-zoom button 39w, the focus lens FL according to Equation 4 below. The target position of F _A is obtained.

Accordingly, since focusing is performed even while the user presses the wide-angle zoom button 39w, the user can see a clear image.

As described above, according to the zooming method of the digital image processing apparatus according to the present invention, the focusing operation of the focus lens is performed corresponding to the zooming operation of the zoom lens. Accordingly, since the input image displayed during the time when the zoom lens is moved is not blurred, the user can see the clear image even during the time when the zooming button is pressed.

The present invention is not limited to the above embodiments, but may be modified and improved by those skilled in the art within the spirit and scope of the invention as defined in the claims.

Claims (7)

A zooming method of a digital image processing apparatus having a zooming button, a zoom lens, and a focusing lens, wherein the zooming lens is moved in units of a set moving distance during a time when the zooming button is pressed. (a) obtaining a target position of the zoom lens corresponding to the set movement distance from the current position of the zoom lens, (b) obtaining a target position of the focus lens corresponding to the target position of the zoom lens, and and (c) simultaneously moving the zoom lens and the focus lens to the respective target positions. The method of claim 1, A zooming method in which the steps (a) to (c) are repeatedly performed while the zooming button is pressed. The method of claim 2, wherein in step (b), A zooming method for obtaining a target position of the focus lens by using a first focusing range of the focus lens corresponding to a current position of the zoom lens and a second focusing range of the focus lens corresponding to a target position of the zoom lens. . The method of claim 3, wherein in step (b), A zooming method, wherein a target position of the focus lens is obtained by a ratio of the second focusing range to the first focusing range. The method of claim 4, wherein in step (b), The current position of the focus lens is F _A , the lower limit position of the first focusing range is F _LA , the upper limit position of the first focusing range is F _HA , the target position of the focus lens is F _B , and the second focusing range is When the lower limit position is F _LB and the upper limit position of the second focusing range is F _HB ,

Zooming method for obtaining the target position of the focus lens by the following equation. The method of claim 1, wherein step (c) comprises (c1) obtaining and setting a moving speed of the focus lens corresponding to a set moving speed of the zoom lens; And (c2) A zooming method comprising simultaneously moving the zoom lens and the focus lens to the respective target positions according to the set moving speeds. The method of claim 1, wherein in step (c1), A zooming method, wherein a moving speed of the focus lens is obtained such that a time at which the zoom lens moves to a target position of the zoom lens and a time at which the focus lens moves to a target position of the focus lens are the same.

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